Effects of aboveground and belowground litter inputs on the balance of soil new and old organic carbon under the typical forests in subtropical region

doi:10.13287/j.1001-9332.202103.008

Abstract

Abstract: Litter is one of the most important factors controlling the accumulation, stabilization, and turnover of soil organic carbon (SOC) in forests. There is a knowledge gap of the impacts of aboveground and belowground litter inputs on the balance of new and old SOC under different forests in subtropical region. We examined the effects of aboveground and belowground litter inputs on SOC turnover using isotopic tracing technique, based on a 3-year C3 plants/C4 soil replacement experiment in natural forest (NF), Masson pine (Pinus massoniana) plantation (PM) and Chinese fir (Cunninghamia lanceolata) plantation (CL). Our results showed that forest types, litter treatments, and sampling time significantly affected SOC contents, δ¹³C, new and old SOC contents. Moreover, there were significant interactions between forest types and litter treatments. Litter input increased SOC content and net SOC increment, with higher sensitivity of NF than CL. Litter inputs decreased soil δ¹³C, with lower values in NF and PM compared to CL. For PM, the new SOC content in belowground litter treatment was significantly higher than that in aboveground litter treatment. The contents of old SOC were lower in belowground litter treatment than aboveground litter treatment in the NF and CL. Above- and below-ground biomass were positively correlated with SOC content and net increment. Belowground litter biomass were positively correlated with soil C/N ratio and new SOC content. Our results implied that belowground litter input had stronger effects on SOC turnover compared to aboveground litter input, with the effects varying among different forests. Our results provided new information on SOC accumulation and on sustainable management of the typical forests in subtropical region.

Key words: subtropical forest, litter input, soil organic carbon, ¹³C stable isotope, soil organic carbon turnover

HONG Xiao-min, WEI Qiang, LI Meng-jiao, YU Tan-wei, YAN Qiang, HU Ya-lin. Effects of aboveground and belowground litter inputs on the balance of soil new and old organic carbon under the typical forests in subtropical region[J]. Chinese Journal of Applied Ecology, 2021, 32(3): 825-835.

References 51

[1]	Mckinley DC, Ryan MG, Birdsey RA, et al. A synthesis of current knowledge on forests and carbon storage in the United States. Ecological Applications, 2011, 21: 1902-1924
[2]	Dixon RK, Brown S, Houghton RA, et al. Carbon pools and flux of global forest ecosystems. Science, 1994, 263: 185-190
[3]	Schimel. Ecological controls over global soil carbon sto-rage. Bulletin of the Ecological Society of America, 1995, 76: 384-385
[4]	苏永中, 赵哈林. 土壤有机碳储量、影响因素及其环境效应的研究进展. 中国沙漠, 2002, 22(3): 19-27 [Su Y-Z, Zhao H-L. Research progress on soil organic carbon storage, influencing factors and environmental effects. Journal of Desert Research, 2002, 22(3): 19-27]
[5]	周国逸, 熊鑫. 土壤有机碳形成机制的探索历程. 热带亚热带植物学报, 2019, 27(5): 481-490 [Zhou G-Y, Xiong X. Exploration history of soil organic carbon formation mechanisms. Journal of Tropical and Subtropical Botany, 2019, 27(5): 481-490]
[6]	Rasse DP, Rumpel C, Dignac MF. Is soil carbon mostly root carbon? Mechanisms for a specific stabilisation. Plant and Soil, 2005, 269: 341-356
[7]	Schmidt MWI, Torn MS, Abiven S, et al. Persistence of soil organic matter as an ecosystem property. Nature, 2011, 478: 49-56
[8]	Fekete I, Kotroczó Z, Varga C, et al. Alterations in forest detritus inputs influence soil carbon concentration and soil respiration in a Central-European deciduous forest. Soil Biology and Biochemistry, 2014, 74: 106-114
[9]	Leff JW, Wieder WR, Taylor PG, et al. Experimental litterfall manipulation drives large and rapid changes in soil carbon cycling in a wet tropical forest. Global Change Biology, 2012, 18: 1-11
[10]	阮超越, 刘小飞, 吕茂奎, 等. 杉木人工林凋落物添加与去除对土壤碳氮及酶活性的影响. 土壤学报, 2020, 57(4): 954-962 [Ruan C-Y, Liu X-F, Lv M-K, et al. Effects of litter addition and removal on soil carbon and nitrogen and enzyme activities in Chinese fir plantation. Acta Pedologica Sinica, 2020, 57(4): 954-962]
[11]	Crow SE, Lajtha K, Filley RT, et al. Sources of plant-derived carbon and stability of organic matter in soil: Implications for global change. Global Change Biology, 2009, 15: 2003-2019
[12]	林宝平, 何宗明, 郜士垒, 等. 去除根系和凋落物对滨海沙地3种防护林土壤碳氮库的短期影响. 生态学报, 2017, 37(12): 4061-4071 [Lin B-P, He Z-M, Gao S-L, et al. Short-term effects of root exclusion and litter removal on sandy soil carbon and nitrogen pools in three coastal plantation forests. Acta Ecologica Sinica, 2017, 37(12): 4061-4071]
[13]	Hatton PJ, Castanha C, Torn MS, et al. Litter type control on soil C and N stabilization dynamics in a temperate forest. Global Change Biology, 2015, 21: 1358-1367
[14]	Bird JA, Torn MS. Fine roots vs. needles: A comparison of 13C and 15N dynamics in a ponderosa pine forest soil. Biogeochemistry, 2006, 79: 361-382
[15]	Mambelli S, Bird JA, Gleixner G, et al. Relative contribution of foliar and fine root pine litter to the molecular composition of soil organic matter after in situ degradation. Organic Geochemistry, 2011, 42: 1099-1108
[16]	刁浩宇, 王安志, 袁凤辉, 等. 长白山阔叶红松林演替序列植物-凋落物-土壤碳同位素特征. 应用生态学报, 2019, 30(5): 1435-1444 [Diao H-Y, Wang A-Z, Yuan F-H, et al. Stable carbon isotopic characteristics of plant-litter-soil continuum along a successional gradient of broadleaved Korean pine forests in Changbai Mountain, China. Chinese Journal of Applied Ecology, 2019, 30(5): 1435-1444]
[17]	喻阳华, 程雯, 杨丹丽, 等. 黔西北次生林优势树种叶片-凋落物-土壤连续体有机质碳稳定同位素特征. 生态学报, 2018, 38(24): 8733-8740 [Yu Y-H, Cheng W, Yang D-L, et al. Carbon stable isotopic chara-cteristics of organic matter in the leaf-litter-soil conti-nuum of dominant tree species in a secondary forest in northwestern Guizhou. Acta Ecologica Sinica, 2018, 38(24): 8733-8740]
[18]	Cheng XL, Luo YQ, Chen JQ, et al. Short-term C4 plant Spartina alterniflora invasions change the soil carbon in C3 plant-dominated tidal wetlands on a growing estuarine Island. Soil Biology and Biochemistry, 2006, 38: 3380-3386
[19]	商素云, 姜培坤, 宋照亮, 等. 亚热带不同林分土壤表层有机碳组成及其稳定性. 生态学报, 2013, 33(2): 416-424 [Shang S-Y, Jiang P-K, Song Z-L, et al. Composition and stability of organic carbon in the top soil under different forest types in subtropical China. Acta Ecologica Sinica, 2013, 33(2): 416-424]
[20]	刘益君, 闫文德, 伍倩, 等. 亚热带樟树人工林土壤呼吸对凋落物处理的响应. 中南林业科技大学学报, 2015, 35(4): 83-88 [Liu Y-J, Yan W-D, Wu Q, et al. Response of soil respiration to litter treatment of Cinnamomum camphora in subtropical area. Journal of Central South University of Forestry ＆ Technology, 2015, 35(4): 83-88]
[21]	高强, 马明睿, 韩华, 等. 去除和添加凋落物对木荷林土壤呼吸的短期影响. 生态学杂志, 2015, 34(5): 1189-1197 [Gao Q, Ma M-R, Han H, et al. Short-term effects of aboveground litter exclusion and addition on soil respiration in a Schima superba forest in Zhejiang province, Eastern China. Chinese Journal of Ecology, 2015, 34(5): 1189-1197]
[22]	吴越, 马红亮, 尹云锋, 等. 凋落物去除和氮添加对亚热带阔叶林土壤不同组分碳、氮的影响. 应用生态学报, 2019, 30(9): 2923-2932 [Wu Y, Ma H-L, Yin Y-F, et al. Effects of litter removal and nitrogen addition on carbon and nitrogen in different soil fractions in a subtropical broad-leaved forest. Chinese Journal of Applied Ecology, 2019, 30(9): 2923-2932]
[23]	Lajtha K, Townsend KL, Kramer MG, et al. Changes to particulate versus mineral-associated soil carbon after 50 years of litter manipulation in forest and prairie experimental ecosystems. Biogeochemistry, 2014, 119: 341-360
[24]	Fang X, Zhao L, Zhou GY, et al. Increased litter input increases litter decomposition and soil respiration but has minor effects on soil organic carbon in subtropical forests. Plant and Soil, 2015, 392: 139-153
[25]	Lajtha K, Bowden RD, Nadelhoffer K. Litter and root manipulations provide insights into soil organic matter dynamics and stability. Soil Science Society of America Journal, 2014, 78: 261-269
[26]	Liu XF, Lin TC, Vadeboncoeur MA, et al. Root litter inputs exert greater influence over soil C than does aboveground litter in a subtropical natural forest. Plant and Soil, 2019, 444: 489-499
[27]	王清奎. 碳输入方式对森林土壤碳库和碳循环的影响研究进展. 应用生态学报, 2011, 22(4): 1075-1081 [Wang Q-K. Responses of forest soil carbon pool and carbon cycle to the changes of carbon input. Chinese Journal of Applied Ecology, 2011, 22(4): 1075-1081]
[28]	凌华, 陈光水, 陈志勤. 中国森林凋落量的影响因素. 亚热带资源与环境学报, 2009, 4(4): 66-71 [Ling H, Chen G-S, Chen Z-Q. Controlling factors of litterfall in China’s forest. Journal of Subtropical Resources and Environment, 2009, 4(4): 66-71]
[29]	黄石德, 黄雍容, 高伟, 等. 沿海拔梯度武夷山3种典型森林凋落物及养分归还动态. 热带亚热带植物学报, 2020, 28(4): 394-402 [Huang S-D, Huang Y-R, Gao W, et al. Dynamics of litterfall and nutrient return in three typical forests of Wuyi Mountain along altitudinal gradient. Journal of Tropical and Subtropical Botany, 2020, 28(4): 394-402]
[30]	徐剑武. 莽山三种森林类型凋落物对土壤有机碳及大量养分的影响. 硕士论文. 长沙: 中南林业科技大学, 2014 [Xu J-W. Effect of Three Kinds of Forest Litter in Mangshan on Soil Organic Carbon and Macronu-trients. Master Thesis. Changsha: Central South University of Forestry ＆ Technology, 2014]
[31]	Cotrufo MF, Wallenstein MD, Boot CM, et al. The microbial efficiency-matrix stabilization (MEMS) framework integrates plant litter decomposition with soil organic matter stabilization: Do labile plant inputs form stable soil organic matter? Global Change Biology, 2013, 19: 988-995
[32]	郭忠玲, 郑金萍, 马元丹, 等. 长白山各植被带主要树种凋落物分解速率及模型模拟的试验研究. 生态学报, 2006, 26(4): 1037-1046 [Guo Z-L, Zheng J-P, Ma Y-D, et al. Researches on litterfall decomposition rates and model simulating of main species in various forest vegetations of Changbai Mountains, China. Acta Ecologica Sinica, 2006, 26(4): 1037-1046]
[33]	聂立凯, 于政达, 孔范龙, 等. 土壤动物对土壤碳循环的影响研究进展. 生态学杂志, 2019, 38(3): 882-890 [Nie L-K, Yu Z-D, Kong F-L, et al. Advance in study on effects of soil fauna on soil carbon cycling. Chinese Journal of Applied Ecology, 2019, 38(3): 882-890]
[34]	González G, Seastedt TR. Soil fauna and plant litter decomposition tropical and subalpine forests. Ecology, 2001, 82: 955-964
[35]	Xu XK, Inubushi K, Sakamoto K. Effect of vegetations and temperature on microbial biomass carbon and metabolic quotients of temperate volcanic forest soils. Geoderma, 2006, 136: 310-319
[36]	Bauhus J, Paré D, Coté L. Effects of tree species, stand age and soil type on soil microbial biomass and its activity in a southern boreal forest. Soil Biology and Biochemistry, 1998, 30: 1077-1089
[37]	Pisani O, Lin LH, Lun OOY, et al. Long-term doubling of litter inputs accelerates soil organic matter degradation and reduces soil carbon stocks. Biogeochemistry, 2016, 127: 1-14
[38]	Ehleringer JR, Buchmann N, Flanagan LB. Carbon isotope ratios in belowground carbon cycle processes. Ecological Applications, 2000, 10: 412-422
[39]	Zhang WD, Wang SL. Effects of NH4+ and NO3- on litter and soil organic carbon decomposition in a Chinese fir plantation forest in South China. Soil Biology and Biochemistry, 2012, 47: 116-122
[40]	Liao JD, Boutton TW, Jastrow JD. Organic matter turnover in soil physical fractions following woody plant invasion of grassland: Evidence from natural 13C and 15N. Soil Biology and Biochemistry, 2006, 38: 3197-3210
[41]	Natelhoffer KJ, Fry B. Controls on natural nitrogen-15 and carbon-13 abundances in forest soil organic matter. Soil Science Society of America Journal, 1988, 52: 1633-1640
[42]	Balesden J. Site-related δ13C of tree leaves and soil organic matter in a temperate forest. Ecology, 1993, 74: 1713-1721
[43]	Hontoria C, Rodríguez-Murillo JC, Saa A. Relationships between soil organic carbon and site characteristics in peninsular Spain. Soil Science Society of America Journal, 1999, 63: 614-622
[44]	Billings SA, Richter DD. Changes in stable isotopic signatures of soil nitrogen and carbon during 40 years of forest development. Oecologia, 2006, 148: 325-333
[45]	Steffens C, Helfrich M, Joergensen RG, et al. Translocation of 13C-labeled leaf or root litter carbon of beech (Fagus sylvatica L.) and ash(Fraxinus excelsior L.) during decomposition: A laboratory incubation experiment. Soil Biology and Biochemistry, 2015, 83: 125-137
[46]	Xia MX, Talhelm AF, Pregitzer KS. Fine roots are the dominant source of recalcitrant plant litter in sugar maple-dominated northern hardwood forests. New Phyto-logist, 2015, 208: 715-726
[47]	Kuzyakov Y. Priming effects: Interactions between living and dead organic matter. Soil Biology and Biochemistry, 2010, 42: 1363-1371
[48]	Luo ZK, Wang EL, Smith C. Fresh carbon input diffe-rentially impacts soil carbon decomposition across natural and managed systems. Ecology, 2015, 96: 2806-2813
[49]	Huang YH, Li YL, Xiao Y, et al. Controls of litter quality on the carbon sink in soils through partitioning the products of decomposing litter in a forest succession series in South China. Forest Ecology and Management, 2010, 261: 1170-1177
[50]	魏圆云, 崔丽娟, 张曼胤, 等. 土壤有机碳矿化激发效应的微生物机制研究进展. 生态学杂志, 2019, 38(4): 1202-1211 [Wei Y-Y, Cui L-J, Zhang M-Y, et al. Research advances in microbial mechanisms underlying priming effect of soil organic carbon mineralization. Chinese Journal of Ecology, 2019, 38(4): 1202-1211]
[51]	郑聚锋, 程琨, 潘根兴, 等. 关于中国土壤碳库及固碳潜力研究的若干问题. 科学通报, 2011, 56(26): 2162-2173 [Zheng J-F, Cheng K, Pan G-X, et al. Perspectives on studies on soil carbon stocks and the carbon sequestration potential of China. Chinese Science Bulletin, 2011, 56(26): 2162-2173]